A capacitor and method for fabricating the same. In one configuration, the capacitor has a silicon substrate, a first and a second silicon dioxide layer over the silicon substrate, and silicon nitride fins between the silicon dioxide layers. The capacitor further includes a dielectric layer over the silicon nitride fins and metal vias in the dielectric layer.
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1. A method of fabricating a capacitor, the method comprising:
receiving a silicon substrate with a first silicon dioxide layer over the silicon substrate;
depositing a silicon nitride layer over the first silicon dioxide layer;
patterning the silicon nitride layer to form a plurality of silicon nitride fins;
growing a silicon film selectively from the silicon nitride fins; and
depositing a dielectric layer over the silicon nitride layer.
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The present invention relates to integrated circuits. More particularly, the present invention relates to a capacitor formed in a vertical manner.
Deep trench capacitors are known to require the deposition and planarization of doped polysilicon using techniques such as chemical mechanical planarization (“CMP”) to achieve a flat surface over a silicon layer after its deposition. However, utilizing CMP is not ideal because it involves multi-stage processes and is relatively expensive. Other capacitors are also known to have many mask levels and a complex process flow.
Accordingly, one example aspect of the present invention is a capacitor. The capacitor includes a silicon substrate and a silicon dioxide layer over the silicon substrate. There is a silicon nitride fin over the silicon dioxide layer. The silicon nitride fin may also have a dielectric layer over the fin.
Another example of the present invention is a method for fabricating a capacitor. The method includes receiving a silicon substrate with a silicon dioxide layer over the silicon substrate. A depositing step deposits a silicon nitride layer over the silicon dioxide layer. A patterning step patterns the silicon nitride layer to form a plurality of silicon nitride fins. Silicon film is grown selectively from the silicon nitride fins. A depositing step deposits a dielectric over the silicon nitride layer.
The subject matter which is regarded as the invention is particularly pointed out and distinctly claimed in the claims at the conclusion of the specification. The foregoing and other objects, features, and advantages of the invention are apparent from the following detailed description taken in conjunction with the accompanying drawings in which:
The present invention is described with reference to embodiments of the invention, but shall not be limited to the referenced embodiments. Throughout the description of the present invention, references are made to
The silicon nitride fins 112 may be formed by a dry etch selective to both the second silicon dioxide layer 108 and the silicon nitride layer 106. The silicon nitride layer 106 and the second silicon dioxide layer 108 are patterned using standard photolithography and dry etch, stopping on the first silicon dioxide layer 104. The dry etch may be composed of two steps. The first step is a dry etch step that is capable of etching silicon dioxide selective to silicon, and the second dry etch process is capable of etching silicon nitride selective to silicon dioxide. The result may be a pillar-like dual film pattern feature located over the first silicon dioxide layer 102.
In another embodiment, the second silicon dioxide layer 108 may be excluded. Instead, silicon nitride fins 112 can be formed using a dry etch process capable of etching silicon nitride selective to silicon oxide, etching the silicon nitride layer 106 alone.
Growing silicon from the silicon nitride fins 112 causes the silicon to grow from each opposing wall of adjacent fins until the silicon film 110 fills the space between the walls. The resulting silicon film 110 may be deposited exclusively on opposing walls of the silicon nitride fins 112, grow upward above the silicon nitride fins 112, or selectively grown to cease at any time depending on the amount of growth desired. The second silicon dioxide layer 108 can be used as an oxide cap or it can be excluded and the silicon film 110 can be polished.
Using the second silicon dioxide layer 108 as an oxide cap over the silicon nitride layer 106 during the selective growth process helps ensure that the silicon film 110 does not grow from the top of the nitride layer 106 in a spherical manner. The second silicon dioxide layer 108 is placed over the silicon nitride layer 106 to create isolation between the metallic-like SiN of the opposing walls of adjacent silicon nitride fins 112, which are on the left and the right of the silicon film 110. As long as the growth is stopped at reasonable time, the silicon film 110 should not grow above the height of the silicon nitride fins 112 because of the isolation. The silicon nitride fins 112 can then be filled with material. This process may be beneficial because it is a simple and inexpensive process that does not require polishing the silicon film 110.
In another embodiment, the second silicon dioxide layer 108 may be excluded. Excluding the second dioxide layer 108 enables the silicon film 110 to grow over of the silicon nitride layer 106 and above the height of the silicon nitride fins 112. In this process, the silicon film 110 may be polished back using chemical mechanical planarization (“CMP”).
The silicon film 110 can be in-situ doped with phosphorus, arsenic, or boron. In addition, it may be implanted with any dopant species, which causes the silicon film 110 to be conductive.
During depositing step 606, a silicon nitride layer is deposited over the first silicon dioxide layer. In one embodiment, the silicon nitride layer may be in direct contact with the first silicon dioxide layer. After depositing step 606 is complete, the method continues to patterning step 608.
During patterning step 608, the silicon nitride layer is patterned to form a plurality of silicon nitride fins. After patterning step 608 is complete, the method continues to depositing step 610.
During depositing step 610, a second silicon dioxide layer is deposited over the silicon nitride layer. In one embodiment, the second silicon dioxide layer is in physical contact with the silicon nitride layer. After depositing step 610 is complete, the method continues to growing step 612.
During growing step 612, a silicon film is selectively grown from the silicon nitride fins. After growing step 612 is complete, the method continues to doping step 614.
During doping step 614, the silicon film is doped. In one embodiment, the silicon film can be implanted with a dopant species such that the silicon film is electrically conductive. The dopant species may be selected from phosphorus, arsenic, and boron. An activation anneal is needed to electrically activate the dopants in the case where the silicon is implanted. In another embodiment, the silicon film may be doped while being grown from the silicon nitride fin. After doping step 614 is complete, the method continues to depositing step 616.
During depositing step 616, a dielectric layer is deposited over the silicon nitride layer. In one embodiment, the dielectric layer may be flowable oxide. In another embodiment, the dielectric layer may be selected from boron silicate Glass (BSG), boron phosphorus silicate glass (BPSG), and phosphorus silicate glass (PSG). After depositing step 616 is complete, the method continues to forming step 618.
During forming step 618, metal vias are formed through the dielectric layer. In this embodiment, the metal vias may be in electrical contact with the silicon film.
At depositing step 610, the second silicon dioxide layer is deposited on the silicon nitride layer. The silicon nitride layer may be in physical contact with the second silicon dioxide layer. After depositing layer 610, patterning steps 704 and 608 are performed.
At patterning steps 704 and 608, the second silicon dioxide layer and the silicon nitride layer are patterned. In one embodiment, the silicon nitride layer is patterned at patterning step 608 before the second silicon layer is patterned at patterning step 704. After pattering steps 704 and 608, the method continues to growing step 612, doping step 614, depositing step 616, and forming step 618 described above.
At polishing step 804, the silicon film is polished. After polishing step 804, the method continues to depositing step 616 and forming step 618 described above.
Silicon nitride fins 112 are formed over the first silicon dioxide layer 104. The silicon nitride fins 112 may be formed using a dry etch selective to both the second silicon dioxide layer 108 and the silicon nitride layer 106. The second silicon dioxide layer 108 and the silicon nitride layer 106 may be patterned to form any desired shape, such as a square or rectangle.
The silicon nitride layer 106 and the second silicon dioxide layer 108 are patterned using standard photolithography and dry etch, stopping on the first silicon dioxide layer 104. The dry etch may be composed of two steps. The first step is a dry etch step that is capable of etching SiO2 selective to Si, and the second dry etch process is capable of etching SiN selective to SiO2. The result may be a pillar-like dual film pattern feature, composed of the second silicon dioxide layer 108 and the silicon nitride layer 106, patterned to form multiple silicon nitride fins 112 with opposing walls located over the first silicon dioxide layer 102.
A silicon film 110 is gown on opposing walls of the silicon nitride fins 112. The silicon film 110 may be grown via epitaxial growth using a process capable of depositing Si on SiN in a selective manner with respect to SiO2, as described, for example, in U.S. Pat. No. 7,687,804 issued Mar. 30, 2010. Growing Si from the silicon nitride fins 112 causes the Si to grow from each opposing wall of adjacent fins until the silicon film 110 fills the space between the walls. The resulting silicon film 110 may be deposited exclusively on opposing walls of the silicon nitride fins 112, grown upward above the silicon nitride fins 112, or selectively grown to cease growth at any time depending on the amount of growth desired.
Using the second silicon dioxide layer 108 as an oxide cap over the silicon nitride layer 106 during the selective growth process ensures that the silicon film 110 does not grow from the top of the nitride layer 106 in a spherical manner. The second silicon dioxide layer 108 is placed over the silicon nitride layer 106 to create isolation between the metallic-like SiN of the opposing walls of adjacent silicon nitride fins 112 that are on the left and the right of the silicon film 110. As long as the growth is stopped at reasonable time, the silicon film 110 may not grow above the height of silicon nitride fins 112 because of the isolation. This process may be beneficial because it is a simple inexpensive process that does not require polishing silicon film 110.
In another embodiment, the second silicon dioxide layer 108 may be excluded. Instead, the silicon nitride fins 112 can be formed using a dry etch process capable of etching SiN selective to SiO, etching silicon nitride layer 106 alone. The result may be a pillar-like film pattern feature, composed of the silicon nitride layer 106, patterned to form the multiple silicon nitride fins 112 with opposing walls located over the first silicon dioxide layer 102.
Instead of using the second silicon dioxide layer 108 can be used as an oxide cap, the second silicon dioxide layer can be excluded and the silicon film 110 can be polished. Excluding the second dioxide layer 108 may enable the silicon film 110 to grow over the silicon nitride layer 106 and above the height of the silicon nitride fins 112. CMP may be utilized to polish back the silicon film 110.
In either embodiment, the silicon film 110 may be in-situ doped with phosphorus, arsenic, and boron or can be implanted with any dopant species. The dopant causes the silicon film 110 to be conductive.
The capacitor array 902 also includes a dielectric layer 114 over the silicon nitride fin 112. After the dielectric layer 114 is deposited, it may be etched and metal vias 116 are deposited in the etched spaces of the dielectric layer 114. Standard lithographic and RIE processes may be utilized to form the metal via 116 contacts to the silicon film 110. A standard M1 processing may be used to wire the contracts.
The flowcharts and diagrams in the Figures illustrate the architecture, functionality, and fabrication of possible implementations of a memory array device according to various embodiments of the present invention. It should be noted that, in some alternative implementations, the fabrication steps depicted in the flowchart and description may occur out of the order noted, depending upon the functionality involved.
The descriptions of the various embodiments of the present invention have been presented for purposes of illustration, but are not intended to be exhaustive or limited to the embodiments disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein was chosen to best explain the principles of the embodiments, the practical application or technical improvement over technologies found in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.
Doris, Bruce B., Khakifirooz, Ali, Cheng, Kangguo, Reznicek, Alexander, Hashemi, Pouya
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